ES2289737T3 - DEVICE AND PROCEDURE FOR DYNAMIC CONTROL OF THE COMBUSTION OF A BURNER IN AN ARC ELECTRIC OVEN. - Google Patents

Abstract

Apparatus for dynamic monitoring of the combustion of a burner (8) emitting a flame (9) through an aperture (8') at one end located above a bath of molten metal (3) covered by a charge of metal scrap (5) uses a contact-less arrangement situated outside the arc furnace to estimate the distance between the end of the burner and a target formed by the adjacent layer of scrap metal. It includes a source that emits a signal, preferably in the form of a pulsed laser beam, passing through the inside the burner in the direction of the target, and a detector (11) that captures the signal reflected by the target and also passing through the burner.

Description

Device and dynamic control procedure of the combustion of a burner in an electric arc furnace.

Object of the invention

The present invention relates to a burner combustion dynamic control device of an electric steel furnace, in particular of an oven electric arc, with a view to improving or optimizing performance Oven energy.

The invention also relates to procedure that the device uses.

Technological background and state of the art

It is known that an electric arc furnace, succinctly referred to hereafter as "arc furnace", It comprises several burners, generally arranged on the wall oven side. In addition, the load of a steel arc furnace It consists mainly of metallic waste that can contain declassified parts or remains of cast iron, steel or ferrous metals, which will be referred to interchangeably hereinafter "shrapnel (s)" or "scrap (s)".

In arc furnaces burners are used that employ a pair of oxidizing gas / gaseous or liquid fuel, preferably oxygen or air as a combustion gas with, for example, natural gas as fuel. These burners are piloted and usually controlled according to a predefined operating mode that determines the oxidizing oxygen / fuel gas ratio, as well as the duration of operation of the burner, regardless of fact that the operating efficiency of each burner individual depends on the effective load of scrap that is It is in front (of the flame) of the burner.

The use of operating modes preprogrammed burners suffers, in particular, from the following inconveniences:

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I dont know takes into consideration that the effectiveness of each individual burner Depends on the effective loading of scrap in front of this burner particular. Consequently, a significant part of the energy consumed by the burner is used with poor performance, since the burners are used according to an operating scheme arbitrary, even if the merger has been carried out and there is no longer enough scrap in front of the burner;

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also, if one more piece of scrap metal heavy or bulky that the others accidentally falls too near a burner that works with a long flame, the flame can deviate and damage the oven walls, causing eventually for that reason dangerous water leaks from refrigeration.

To improve burner performance in function of the electrical energy and fossil input, a Dynamic burner control. Dynamic control is understood as a real-time control or regulation that takes into account combustion operating conditions at any given time, by opposition to a preprogrammed operating point.

Control devices of the operation or regulation of an electric arc furnace. In particular, the European patent application EP-A-1 457 575 describes a device for observing the loading of machine guns in an oven steel mill comprising several burners arranged above the bath level in fusion. At least one of the burners is equipped with a chamber arranged inside the burner. By example, it can be an endoscopic infrared camera arranged so that its aiming axis coincides with the axis longitudinal burner. This camera and the control means that they are associated allow you to monitor the fusion of the load of shrapnel in the course of time and adapt the loading rate of shrapnel baskets.

In the American patent US-B-6,440,355 describes a optical measuring device, retractable inside a housing of protection and solidarity of the system of maintenance of a lance of oxygen in an oxygen converter. This measuring device comprises a laser optical head suitable for sending a beam incident on a target area in the oven, such as the surface from the slag, receive and detect the reflected beam and determine, comparing the two beams, the distance at which the area is Diana. This device has the sole purpose of allowing adjustment correct distance separating the slag from the head of the oxygen lance

In the American patent US-A-5,125,745 further describes a mobile inspection apparatus that can be arranged in the proximity of the opening of an oven arranged horizontally. He apparatus comprises a laser that can illuminate the coating internal oven. The light diffused by it can be received by a self-sweeping linear detection network and coupled to a computer to provide a graphical representation of the state of wear of the internal lining of the oven.

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Objectives of the invention

The present invention aims to propose a solution that allows to solve the inconveniences of the state of the technique.

In particular, the present invention is intended provide a dynamic control procedure, that is, in Operational course of mounted fuel burners on the walls of the arc furnace.

A complementary objective of the invention is improve, and even optimize, the burner performance of the arc furnace

Another goal is still to obtain a reliable and reproducible operation of the arc furnace with a view to obtain an optimal fusion of a given amount of scrap, by medium of lower electrical energy and reduced gas consumption with respect to the systems used in the state of the technique.

Main characteristic elements of the invention

A first object of the present invention is refers to a device for dynamic combustion control of a gas or liquid fuel burner in an oven electric arc, particularly in a steel arc furnace, said burner emitting a flame through an opening located at the end of the burner, above a molten metal bath crowned in turn by a shrapnel load, characterized in that it comprises non-contact measuring means, located in the outside of the arc furnace, to estimate the distance between the burner end and a target consisting of solid shrapnel located in front of said end, said means comprising a source that emits a signal that passes into said burner, or of another burner, in the direction of said target, and a detector in the that said signal reflected by the target is captured, also passing inside said burner, respectively of the other burner.

According to a first preferred embodiment of the invention, the means of measuring distance between the end of the burner and solid shrapnel comprise a detection head Optical distance sensor type located inside or in the back of the burner, which preferably has a laser pulsed emitting an incident beam that points to shrapnel to through an opening located on the burner shaft, and a appropriate photodetector to receive the laser beam reflected by the shrapnel.

According to this embodiment, the head of detection is set to perform distance measurement on a high temperature target, preferably at a temperature that can reach 1,500 ° C, and / or to effect said measurement in an environment or in an optical path that presents calls.

Advantageously, the detection head is equipped with cooling means, for example using Water.

Preferably, the laser is a laser diode semiconductor that emits in the infrared domain, equipped with a collimator lens and a filter, preferably a filter interference, to eliminate or attenuate background noise linked to the radiation of the arc furnace.

Always preferably, the photodetector it comprises a receiving lens with an interference filter and at minus one photodiode, coupled to an electronic detection system high frequency

Still advantageously, the photodiode and, by both, the detection head are coupled by fiber optical to the high frequency electronic detection system, what which allows the latter to be better protected from the environment possibly difficult where the sensor is.

Always advantageously, the window of view of the detection head is equipped with protective means of swept by a gas under pressure, such as nitrogen, compressed air or natural gas.

Always according to the invention, the head of detection can be configured to be able to measure distances that They reach up to 5 meters.

The device of the invention further comprises regulation means to adjust a relationship in real time oxidizing gas / fuel at the burner feed level and / or the burner power and / or the operating time of the burner depending on the distance measured by the head of High frequency detection and electronics.

Preferably, said regulation means are closed loop regulation means.

According to a second preferred embodiment of the invention, the distance measuring means between the burner end and solid shrapnel comprise a system of radar located inside or at the back of the burner.

A second object of the present invention is refers to a burner for electric arc furnace equipped with a dynamic combustion control device such as the one described above

A third object of the present invention is refers to a dynamic combustion control procedure of a burner in an electric arc furnace by means of the device with optical detection head described above, characterized because it comprises the following stages:

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to emit an incident pulsed laser beam that points to shrapnel through the opening located on the burner shaft;

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detect the beam reflected by the shrapnel;

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deduce the distance between the end of the burner and shrapnel by means of a time measurement of flight, that is, measuring the time interval that elapses between the laser pulses emitted and received respectively;

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adjust a gas ratio oxidizer / fuel at the level of the burner feed and / or the power of the burner and / or the operating time of the burner, preferably according to a closed loop regulation, using as a regulation parameter the distance value measure.

Brief description of the figures

Figure 1 schematically represents in vertical section a steelmaking furnace comprising the device of the invention.

Figures 2A and 2B schematically represent two cases of operation figure illustrating the embodiment of the invention.

Description of a preferred embodiment of the invention

The main object of the invention is to provide the oxifuel burners mounted on the walls of the arc furnace with dynamic combustion control means.

According to a preferred embodiment of the invention, these control means comprise an optical sensor, is say, without contact, located outside the arc furnace, to estimate the distance between the end of the burner and a target constituted by solid shrapnel located in front of said end. The optical sensor is located inside the burner or behind of this and consists of a measuring head comprising a source that emits a beam that passes inside the burner in direction to the target, that is, the scrap not yet melted. The beam it is reflected by the bank in the direction of a detector that found in the measuring head, also passing through the inside of the burner

The oxygen / natural gas ratio used, the operating time and / or burner power will be chosen then depending on the effective loading of scrap in front of each individual burner, which is estimated precisely by of the distance sensor.

Any other means than a medium optical, for example a radar system, to determine distances in a noisy noise environment due to high temperature is also likely to be covered by the object of the invention.

A system for instant measurement of the distance between the end of the burner and the solid scrap must allow the burner operating points to be adjusted and its corresponding operating duration, with a view to avoiding the disadvantages mentioned above and thus increase the effectiveness of the fossil energy contribution.

Based on the signal measured from distance sensor, calculation of operating points dynamic will also allow automatic operation of the burner. The oxygen / natural gas ratio, the power of the burner and the operating duration of each individual burner is will be calculated based on the effective loading of scrap in front of Each burner

In its start-up phase, the burner will use a high oxygen / natural gas ratio and a power  less than its nominal power, which can be, for example, from 5 to 10 megawatts (MW). These conditions will be maintained for as long time as scrap is present in the vicinity of the end of the burner and until a free cavity is created (empty of solid matter) within the junk load in front of the burner.

When said fusion cavity has formed, the burner will be controlled normally in the conditions stoichiometric and at nominal power. The operation of burner should stop as soon as the melting conditions, to avoid any reduction of your effectiveness.

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The distance sensor will be chosen to be able to aim at a target carried at a very high local temperature, without that the measurement is too disturbed by the radiation itself from the target, to the wavelengths used. This sensor must also accommodate the presence of the flames generated by the burner, which in particular can absorb the emitted beam and Received by the sensor.

Advantageously, the measurement principle chosen is as follows:

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a beam Pulsed laser points to the scrap through a central opening of the burner;

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the light reflected is detected by a suitable sensor;

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the distance (D) mentioned above is deduced from a calculation of "flight time" based on the time interval that separates the impulse emitted from the impulse received; since the speed to consider is the speed of light, electronics are required High frequency detection.

An example of installation capable of using the device of the invention, said figure showing a fragmentary view of an arc furnace of steelworks, in vertical section, in which it is schematically illustrated the burner comprising the device of the invention.

The arc furnace comprises in particular a tank 1 closed by a lid 2 provided with cooling means by water. In operation, tank 1 contains a steel bath cast 3 coated, by way of indication, by a layer of slag 4. After refining, the melting steel 3 is poured by a pouring hole well known to the person skilled in the art (not shown). After casting, a new amount is charged  of machine guns 5 in the oven, with the lid 2 open, by means of a basket (not shown). The submachine gun load 5 is melted progressively by means of an electric arc 6 formed between a electrode 7 and molten steel bath 3, with the support of burners 8, well known in the state of the art and that develops flames 9. A sensing head 11 of the sensor type of distance is integrated within the burner according to a form of preferred embodiment of the invention: this comprises in particular a laser diode that generates a pulsed laser beam that points to the scrap 5 through a central opening 8 'of the burner as well as a photodetector arranged at a solid angle that allows you detect the laser beam reflected on the scrap 5.

In normal or efficient burner operation, as mentioned above, a free cavity is formed by the fusion in front of the end of the burner 8, as illustrated in the figure 2A. This cavity defines a distance D between the end 8 ' of the burner and the front scrap 5 still in solid state. This distance D is measured precisely by the device of the invention. In this situation, the burner will be fed with oxygen and fuel (natural gas, designated NG in Figures 2A and 2B) according to stoichiometric proportions. Conversely, in the situation illustrated in figure 2B, in which the merger is not optimal and in which there is a partial disappearance of the fusion cavity, distance D measured fatally with with respect to the previous situation and the burner will be fed with an oxygen / natural gas ratio greater than the ratio stoichiometric and / or with reduced power with respect to the rated power

The invention has the advantage that a Dynamic and automatic burner control ensures your optimal operation in a reliable and reproducible way with a view to obtain an improved or optimized scrap fusion through of a reduced consumption of electricity and gas, using The better the energy of the burner.

Claims (14)

1. Device for the dynamic control of the combustion of a gas or liquid fuel burner (8) in an electric arc furnace, in particular in a steel arc furnace, said burner (8) emitting a flame (9) ) by an opening located at one end (8 ') of the burner (8) above a molten metal bath (3) topped in turn by a shrapnel load (5), characterized in that it comprises contactless measuring means , located outside the arc furnace, to estimate the distance (D) between one end (8 ') of the burner (8) and a target consisting of solid shrapnel (5) located in front of said end (8'), comprising said means a source that emits a signal that passes into said burner (8), or another burner, in the direction of said target, and a detector in which said signal reflected by the target is captured, also passing into said burner (8), respectively of the other burner. Device according to claim 1, characterized in that the distance measuring means (D) between the end (8 ') of the burner (8) and the solid shrapnel (5) comprise a sensing head (11) of the sensor type of optical distance, located inside or at the rear of the burner (8), which has a preferably pulsed laser that emits an incident beam pointing to the shrapnel (5) through an opening located on the burner shaft (8 ) and an appropriate photodetector to receive the laser beam reflected by shrapnel (5). Device according to claim 2, characterized in that the detection head (11) is configured to perform the distance measurement on a target carried at high temperature, preferably at a temperature that can reach 1,500 ° C, and / or to perform said measurement in an environment or an optical path that presents flames. Device according to claim 2 or 3, characterized in that the detection head (11) is equipped with cooling means. 5. Device according to any of claims 2 to 4, characterized in that the laser is a semiconductor laser diode that emits in the infrared domain, equipped with a collimating lens and with a filter, preferably an interferential filter, to eliminate or attenuate the noise of background linked to the arc furnace's own radiation. Device according to any of claims 2 to 5, characterized in that the photodetector comprises a reception lens with an interference filter and at least one photodiode, coupled to an electronic high frequency detection system. 7. Device according to claim 6, characterized in that the photodiode is coupled by optical fiber to the electronic high frequency detection system. A device according to any one of claims 2 to 7, characterized in that the sight window of the detection head (11) is equipped with protection means for sweeping by a pressurized gas such as nitrogen, compressed air or natural gas. Device according to any of claims 2 to 8, characterized in that the detection head (11) is configured to be able to measure distances that reach up to 5 meters. 10. Device according to any of the preceding claims, characterized in that it further comprises regulation means for adjusting in real time a combustion gas / fuel ratio to the level of the burner feed and / or the burner power and / or the operating time of the burner depending on the distance (D) measured by the detection head (11) and the high frequency electronics. Device according to claim 10, characterized in that said regulation means are closed loop regulation means. 12. Device according to claim 1, characterized in that the distance measuring means (D) between the end (8 ') of the burner (8) and the solid shrapnel comprise a radar system located inside or at the rear of the burner (8). 13. Burner for electric arc furnace equipped with a dynamic combustion control device according to any of the preceding claims. 14. A dynamic combustion control method of a burner (8) in an electric arc furnace by means of the device with optical detection head (11) according to any of claims 2 to 11, characterized in that it comprises the following steps: - emit an incident pulsed laser beam that point to shrapnel (5) through the opening in the shaft of the burner (8); - detect the beam reflected by shrapnel (5); - deduct the distance (D) between the end of the burner (8 ') and shrapnel (5) by means of a time measurement of flight, that is, measuring the time interval that elapses between the laser pulses emitted and received respectively; - adjust a gas ratio oxidizer / fuel at the level of the burner feed and / or the power of the burner and / or the operating time of the burner, preferably according to a closed loop regulation, using as a regulation parameter the distance value (D) measure.